Xiumei Bai1, Xi Lin2, Josephine Drayton1, Yulan Liu1, Cheng Ji3, Jack Odle1. 1. Laboratory of Developmental Nutrition, Department of Animal Science, North Carolina State University, Raleigh, NC; and. 2. Laboratory of Developmental Nutrition, Department of Animal Science, North Carolina State University, Raleigh, NC; and lin_xi@ncsu.edu. 3. National Laboratory of Animal Nutrition, College of Animal Science and Technology, China Agricultural University, Beijing, China.
Abstract
BACKGROUND: Utilization of energy-dense lipid fuels is critical to the rapid development and growth of neonates. OBJECTIVE: To increase efficiency of milk fat utilization by newborn pigs, the effect of clofibrate on in vivo and in vitro long-chain fatty acid (LCFA) oxidation was evaluated. METHODS: Newborn male pigs were administered 5 mL of vehicle (2% Tween 80) with or without clofibrate (75 mg/kg body weight) once daily via i.g. gavage for 4 d. Total LCFA oxidative capacity was measured in respiration chambers after gastric infusion (n = 5 per treatment) with isoenergetic amounts of [1-(14)C]triglycerides (TGs), either oleic acid (18:1n-9) TG [3.02 mmol/kg body weight (BW)(0.75)] or erucic acid (22:1n-9) TG (2.46 mmol/kg BW(0.75)). Total expired (14)CO2 was collected and quantified at 20-min intervals over 24 h. Hepatic in vitro LCFA oxidation was determined simultaneously using [1-(14)C]oleic acid and erucic acid substrates. RESULTS: The in vivo 24-h accumulative [1-(14)C]TG oxidation (percentage of energy intake/kg BW(0.75)) tended to increase with clofibrate supplementation (P = 0.10), although there was no difference in the peak or mean utilization rate. The maximal extent of oleic acid TG oxidation was 1.6-fold that of erucic acid TG (P < 0.006). Hepatic in vitro LCFA oxidation increased 61% with clofibrate (P < 0.0008). The increase in mitochondria was 4-fold greater than in peroxisomes. The relative abundance of mRNA increased 2- to 3-fold for hepatic peroxisome proliferator-activated receptor α and its target genes (fatty acyl-coenzyme A oxidase and carnitine palmitoyltransferase) in the pigs that were administered clofibrate (P < 0.04). CONCLUSION: Clofibrate may improve in vivo LCFA oxidative utilization in neonatal pigs.
BACKGROUND: Utilization of energy-dense lipid fuels is critical to the rapid development and growth of neonates. OBJECTIVE: To increase efficiency of milk fat utilization by newborn pigs, the effect of clofibrate on in vivo and in vitro long-chain fatty acid (LCFA) oxidation was evaluated. METHODS: Newborn male pigs were administered 5 mL of vehicle (2% Tween 80) with or without clofibrate (75 mg/kg body weight) once daily via i.g. gavage for 4 d. Total LCFA oxidative capacity was measured in respiration chambers after gastric infusion (n = 5 per treatment) with isoenergetic amounts of [1-(14)C]triglycerides (TGs), either oleic acid (18:1n-9) TG [3.02 mmol/kg body weight (BW)(0.75)] or erucic acid (22:1n-9) TG (2.46 mmol/kg BW(0.75)). Total expired (14)CO2 was collected and quantified at 20-min intervals over 24 h. Hepatic in vitro LCFA oxidation was determined simultaneously using [1-(14)C]oleic acid and erucic acid substrates. RESULTS: The in vivo 24-h accumulative [1-(14)C]TG oxidation (percentage of energy intake/kg BW(0.75)) tended to increase with clofibrate supplementation (P = 0.10), although there was no difference in the peak or mean utilization rate. The maximal extent of oleic acidTG oxidation was 1.6-fold that of erucic acid TG (P < 0.006). Hepatic in vitro LCFA oxidation increased 61% with clofibrate (P < 0.0008). The increase in mitochondria was 4-fold greater than in peroxisomes. The relative abundance of mRNA increased 2- to 3-fold for hepatic peroxisome proliferator-activated receptor α and its target genes (fatty acyl-coenzyme A oxidase and carnitine palmitoyltransferase) in the pigs that were administered clofibrate (P < 0.04). CONCLUSION:Clofibrate may improve in vivo LCFA oxidative utilization in neonatal pigs.